WO2017017212A1 - Adapter for mounting field bus devices used in industrial automation - Google Patents

Abstract

Adapter (1) for mounting e.g. a field bus device (1) on a support rail; a fastening means that cooperates with the adapter (2) is provided for attaching the field bus device (1) to the support rail, and the adapter (2) has an elongate hole for leading the fastening element therethrough.

Description

 DESCRIPTION

Adapter for mounting fieldbus devices for industrial automation

The invention relates to an adapter for electrical, electronic and electromechanical devices and / or components, in particular a field bus device, according to the Merkmaien of the preamble of claim 1.

The invention is based on an electrical device, such as a fieldbus device, for. As input-output distribution modules, power distribution boxes and the like, as is known from DE 297 03 367 U1.

This electrical device has a housing, in particular made of an electrically conductive material, and is provided, for example, with slots into which plug-in connectors can be screwed and tightened depending on the application.

It is known that these electrical devices are arranged on carriers, in particular carrier rails, and fixed via a screw connection. These carrier rails are made of electrically conductive material, so that there is the problem that the electrical device is electrically contacted via its metal housing with the metal carrier rail, which is disadvantageous. In addition, an electrical contact between the electrical device, in particular its housing, and the carrier via the screw, if the screw is also made of a metallic material. Moreover, it is disadvantageous in the electrical appliances on the market that they always have a certain pitch with which they are arranged and fixed on the associated carrier having the corresponding pitch. Due to different grid dimensions of different manufacturers is thus a compatibility with each other is not given.

The invention is therefore based on the object to improve an electrical device with respect to the disadvantages described above.

According to the invention an adapter for mounting in particular a field bus device on a mounting rail (support) is provided, wherein a cooperating with the adapter fastening means for fixing the fieldbus device is provided on the support rail and the adapter for the implementation of the fastener has an elongated opening. By means of the adapter, it is advantageously possible to adapt a constant length of the field bus device or its housing at predetermined distances from mounting rails. This is done by having the adapter for the implementation of the fastener such as a screw, a clip body, a pin, a nail or the like, an elongated opening. As a result, the fieldbus device by means of the adapter securely on one side, preferably on two opposite sides, are securely attached to the support rails, which no longer as known in the art must have a defined distance. But with the adapter according to the invention, it is possible to adapt a constant length of the field device to the extent to which the mounting rails are spaced apart.

In a further development of the invention, an adapter is arranged in each case at one or both ends of a device. In addition, at least one insulating element is provided so that the bottom of the field bus device can be placed on this element. As a result, on the one hand, a spacing of the underside of the housing of the fieldbus device to the pad on which the support rails are arranged, given and on the other hand can be a galvanic isolation to the ground when the insulating (and possibly also to its end arranged adapter) made of an electrically non-conductive material (such as plastic).

The term "insulating member" does not necessarily mean that it is made of an electrically non-conductive material.The insulating member may also be a connecting member of an electrically conductive material.Also, it is important and conceivable that the adapter is made of both conductive and non-conductive material can exist and the insulating of only non-conductive material.

In one embodiment, the insulating element is formed flat between the adapters. In this way, a galvanic separation between the field bus device (in particular if its housing consists of a metallic material) and the mounting surface can be realized in a simple manner.

In a further development of the invention, the connecting element between the adapters has a peripheral frame. This frame can be configured differently high for different fasteners and is in an advantageous manner at each connecting element radially circumferentially the same height. Through this framework, the fieldbus device can be fixed to the insulating. In addition, the frame around the fieldbus device provides some protection or soiling and mechanical damage. In addition, this is also in the edge region of the housing of the fieldbus device, a galvanic isolation, for example, compared to other specified on the mounting rails fieldbus devices given.

In a further development of the invention, the adapter and the insulating element are integrally formed or these parts are separate components. Thus, there are several options available to realize the variable definition of the fieldbus device on the mounting rails by means of the adapter and at the same time to ensure galvanic isolation between, for example, the fieldbus device and its background. In a particularly advantageous manner adapter and insulating element are integrally formed, since this is particularly easy to handle during assembly. The adapter and / or the insulating element are manufactured by means of a plastic injection molding process, because this allows a cost-effective production, in particular with large numbers and different shapes and geometries can be realized by the particular shape during plastic injection molding. In addition, the adapter can also be made of metallic materials, by die casting behavior and / or machining. In this design, it fulfills the function of length compensation to carrier rails of different devices from different manufacturers in an advantageous manner. In the following, the invention will be described with reference to various embodiments, from which corresponding advantages result, and explained with reference to the figures.

As far as is shown in detail, in particular a fieldbus device is designated by 1 in FIG. 1, which comprises, for example, an input E and a plurality of outputs A. The design of the inputs and outputs is variable and has no influence on the invention. However, it is important that the fieldbus device 1 receives a housing which is suitable and designed to be brought into operative connection with an adapter 2 on at least one side, preferably on the two narrow sides (as shown in FIG. 1). The adapter 2 works with a fastening means, here a screw 3, together, wherein the adapter 2 has an elongated opening for the fastening means (for the screw 3). In the area which is located approximately below the two adapters 2, carriers (mounting rails) are present, but not shown. These mounting rails are approximately parallel to each other and have a predetermined distance. Since it may happen that this measure is different in different applications and can thus vary, it is ensured by means of the adapter 2 with its elongated opening that the field bus device 1 readily the various dimensions (different distance dimensions between the two parallel mounting rails) are adjusted can. In Figure 1 it is shown that the two adapters 2 are individual parts which, as well as the housing of the field bus device 1, are suitable and designed with the Housing of fieldbus device 1 cooperate to set this on the mounting rails.

Figure 2 shows a similarly designed field bus device 1, at the ends in turn adapter 2 are arranged with elongated openings for one screw 3. To the field bus device 1 around an insulating member 4 is provided, which is connected to the adapters 2 (for example by an adhesive or welding process) or the adapter 2 are inserted into the insulating member 4 or the insulating member 4 is integrally formed with the adapters 2. In the embodiment according to FIG. 3, only the possibility of galvanic isolation without length compensation is illustrated. The galvanic isolation with the insulating element (in particular the insulating shell shown) does not necessarily require the adapter.

Figure 4 again shows another embodiment of a field bus device 1, at the narrow ends turn adapter 2 are provided to set the field bus device 1 by means of the adapter 2 with its elongated openings and the screws 3 on the mounting rails. Here, the adapter 2 are again designed as individual parts.

FIG. 5 shows a field bus device 1 with adapters 2 with elongated openings, in each of which a screw 3 is inserted. In this embodiment, the adapter 2 are connected to each other via an insulating 4 and thus formed in one piece.

FIG. 6 shows various embodiments of the insulating element 4, which can cooperate with one and the same field bus device 1 according to FIG.

Figure 7a) shows a flat ausgestaltetes insulating 4, each with a tab 5 preferably on the narrow end side. The tab 5 has an elongated opening, as well as the adapter 2 of the field bus device 1, which also has a corresponding elongated opening. By means of this insulating element 4 in Figure 7a) there is a galvanic isolation between the underside of the field bus device 1 and the support surface on which the support rails (not shown here) are arranged. FIG. 7b) shows the same principle, however, the insulating element 4 has a peripheral frame 6. This frame is designed relatively flat and allows the fieldbus device 1 already pretend a position with respect to the insulating element 4, when this is placed on the insulating 4 and thus inserted into the frame 6.

This type of leadership when placing the fieldbus device 1 on the insulating 4 is further improved by the circumferential frame 6 is further pulled upwards (especially up to the top of the housing of the fieldbus device 1 or even beyond), as shown in Figure 7c ) is shown. This not only allows a galvanic separation of the field bus device 1 to the bearing surface, but also a galvanic isolation around the field bus device 1 around it. In addition, this gives a mechanical protection of the sides of the field bus device 1, which is particularly advantageous in harsh environmental conditions.

In the following, the solution according to the invention will be described again in other words.

With regard to the production of the compatibility of electrical devices with each other or in relation to predetermined different grid dimensions of carriers, in particular two parallel running carrier rails, an adapter is provided, which is arranged and fixed end to the housing of the electrical device. This adapter causes a distance compensation between its attachment opening, which is arranged defined to the housing of the electrical device and the corresponding attachment point on the carrier, in particular the two mutually opposite attachment points of the two carrier rails. The attachment points of the carrier are, for example threaded holes into which a screw is screwed. The screw sets the adapter on the carrier, which also at the same time the housing of the electrical device is fixed on the support, since the adapter for spacing compensation is fixedly arranged on the housing of the electrical device. In order to at least compensate for tolerances, but also to use a further grid size flexible To be able to, the opening of the adapter through which the screw is guided, not as a round hole, but as an elongated hole is formed.

In order to realize a galvanic separation between the housing of a metallic material of the electrical device and the at least one carrier, preferably the two parallel carrier rails, also made of a metallic material, is an intermediate layer between the housing and the carrier of an electrically insulating material , z. As plastic provided. This insulator can z. B. are arranged as a plate-shaped element between bottom housing and top support. But it can also have a peripheral edge, is taken over the part of the housing of the electrical device and fixed in its position with respect to the insulator.

Various embodiments of the invention are shown in the figures. Figures 1 and 2 show an electrical device in the form of a field bus module with ehdseitig arranged adapter and an insulator (Figure 2). The carrier, z. B. the carrier system of two mutually parallel carrier rails, is present, but not shown.

Figure 3 also shows a field bus module in which, although no adapter, but a galvanic isolation in the form of an insulator between the metallic housing of the electrical device and the carrier system is present.

Figure 4 again a field bus module with an adapter, which is arranged in each case on the narrow end face of the electrical device. Although there is no insulator between the electrical device and the carrier system, it can be provided. FIG. 5 shows a field bus module with an adapter for compensating differences in length and with an additional function for galvanic isolation in the form of an insulator, the special feature here being that the adapter is formed by the insulator. Such a structure can be easily made of plastic in an injection molding process and simplifies the assembly of the electrical device, since this can be used in the insulator, since it has a peripheral edge for receiving the housing.

Figure 6 shows an electrical device with a predetermined pitch for fastening by means of screws without adapter, but again with insulator between the bottom of the housing of the electrical device and the carrier system, not shown.

Finally, FIG. 7 shows, by way of example, various embodiments of the insulator for electrical isolation between the housing of metallic material of the electrical device and the carrier system, which is likewise not shown, consisting of a metallic material. The insulator is formed in FIG. 7a as a flat plate and can, but need not, also have through openings for the fastening screws on the short end faces. The same applies to the embodiments according to FIGS. 7b and 7c, in which the insulator is not only a flat plate, but has a narrow peripheral edge (FIG. 7b) or a higher peripheral edge (FIG. 7c) into which the housing of the electrical device can be used.

In general, the adapter to compensate for different grid dimensions is a separate component that can be brought into operative connection with the housing of the electrical device and the carrier system (possibly also with the insulator). Alternatively, it is conceivable that the adapter component of the housing of the electrical device is or is formed by the insulator. Depending on the configuration, the adapter may have a round hole, which is in coincidence with the mounting hole of the carrier system, when the electrical device is mounted on this. In order to compensate for different grid dimensions, it is also conceivable that the adapter has a slot, so that different Adapter dimensions can be brought into compliance, in particular when an attachment point is in each case at one end face of the electrical device (thus two opposing attachment points) are provided. This may or may not be the case if only a single point of attachment is provided because the electrical device is to be mounted on a single carrier rail only.

The adapter aileine or if it is formed by the insulator is particularly preferably made of plastic, since then the electrical isolation can be achieved, even if the housing of the electrical device, the mounting screw and the support system made of a metal material.

However, it is also conceivable, for example, for the galvanic separation between housing and carrier system to take place via the insulator (with or without peripheral edge), even if the adapter consists of a metal material and the fastening screw is made of an electrically non-conductive material (such as, for example, US Pat Plastic).

Electrical device with a housing made of an electrically conductive material, characterized in that an adapter is provided to compensate for different pitches in the attachment of the electrical device and / or between a carrier system at the installation of the electrical device and the housing of the electrical device, an insulator is arranged.

LIST OF REFERENCE NUMBERS

1st fieldbus device

2. Adapter

3. screw

4. insulating element

5th tab

6th frame

Claims

PATENT APPLICATIONS Adapter for mounting fieldbus devices for industrial automation

1. Adapter (2) for mounting an electrical device, in particular a fieldbus device (1), on a mounting rail, wherein a with the adapter (2) cooperating fastening means for fixing the fieldbus device (1) is provided on the mounting rail and the adapter (2 ) has an elongated opening for the implementation of the fastener.

2. Adapter (2) according to claim 1, characterized in that in each case an adapter (2) is arranged at each one end of a connecting element (4) or only an adapter (2) is arranged at any end.

3. Adapter (2) according to claim 2, characterized in that the

Isoliereiement (4) between the adapters (2) is formed flat.

4. Adapter (2) according to claim 2, characterized in that the

Insulating element (4) between the adapters (2) has a peripheral frame (6).

5. Adapter (2) according to claim 1, 2, 3 or 4, characterized in that the adapter (2) and the insulating element (4) are formed from one another separate components or in one piece.

6. Adapter (2) according to one of the preceding claims, characterized in that the adapter (2) and / or the Isoiierelement (4) are formed by an electrically non-conductive material.

7. Adapter (2) according to claim 6, characterized in that the adapter (2) and / or the Isoiierelement (4) mitteis a Kunststoffspritzgussvefahrens and / or Metaildruckgussverfahren and / or mechanical machining are made.